Proving $int_0^infty logleft (1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dx =2pi sin theta$Computing...

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Proving $int_0^infty logleft (1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dx =2pi sin theta$


Computing $int_{0}^{pi}lnleft(1-2acos x+a^2right) , dx$Find the integral of log(1 - a/x^2 + 1/x^4) from 0 to infinityEvaluating $int_0^{largefrac{pi}{4}} logleft( cos xright) , mathrm{d}x $$iint_D cos left( frac{x-y}{x+y} right),dA$Evaluate: $int_0^{pi} ln left( sin theta right) dtheta$Computation of $int_0^{pi} frac{sin^n theta}{(1+x^2-2x cdot cos theta)^{frac{n}{2}}} , dtheta$A Challenging Integral $int_0^{frac{pi}{2}}log left( x^2+log^2(cos x)right)dx$Log Sine: $int_0^pi theta^2 ln^2big(2sinfrac{theta}{2}big)d theta.$Prove $cos(2theta) + cosleft(2 left(frac{pi}{3} + thetaright)right) +cosleft(2 left(frac{2pi}{3} + thetaright)right) = 0$Closed form of $int_0^{pi/2} frac{arctan^2 (sin^2 theta)}{sin^2 theta},dtheta$Interesting integral: $I=int_0^1 int_0^1 logleft( cos(pi x)^2 + cos(pi y)^2 right)dxdy$Substitutions for the trigonometric integral $int cos theta cos^5left(sin thetaright) dtheta$













8












$begingroup$



Prove $$int_0^infty log left(1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dx =2pi sin theta$$where $thetain[0,pi]$.




I've met another similar problem,
$$ int_0^{2pi} log(1-2rcos theta +r^2) dtheta=2pi log^+(r^2) $$
I am curious whether there is any relationship between them.



And I got stuck on the proposition in the title. I found that
$$1-2frac{cos 2theta}{x^2}+frac{1}{x^4} =left(frac{1}{x}-e^{itheta}right)left(frac{1}{x}+e^{itheta}right)left(frac{1}{x}-e^{-itheta}right)left(frac{1}{x}+e^{-itheta}right)$$
But I couldn't move on.



Any hints? Thanks in advance.










share|cite|improve this question











$endgroup$












  • $begingroup$
    Maybe you can complete a square and make a substitution afterwards.
    $endgroup$
    – mathreadler
    Mar 11 at 10:30






  • 1




    $begingroup$
    I am not sure about a relationship between them, but both of them can be solved by similar tehniques (Feynman's trick).
    $endgroup$
    – Zacky
    Mar 11 at 11:11
















8












$begingroup$



Prove $$int_0^infty log left(1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dx =2pi sin theta$$where $thetain[0,pi]$.




I've met another similar problem,
$$ int_0^{2pi} log(1-2rcos theta +r^2) dtheta=2pi log^+(r^2) $$
I am curious whether there is any relationship between them.



And I got stuck on the proposition in the title. I found that
$$1-2frac{cos 2theta}{x^2}+frac{1}{x^4} =left(frac{1}{x}-e^{itheta}right)left(frac{1}{x}+e^{itheta}right)left(frac{1}{x}-e^{-itheta}right)left(frac{1}{x}+e^{-itheta}right)$$
But I couldn't move on.



Any hints? Thanks in advance.










share|cite|improve this question











$endgroup$












  • $begingroup$
    Maybe you can complete a square and make a substitution afterwards.
    $endgroup$
    – mathreadler
    Mar 11 at 10:30






  • 1




    $begingroup$
    I am not sure about a relationship between them, but both of them can be solved by similar tehniques (Feynman's trick).
    $endgroup$
    – Zacky
    Mar 11 at 11:11














8












8








8


2



$begingroup$



Prove $$int_0^infty log left(1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dx =2pi sin theta$$where $thetain[0,pi]$.




I've met another similar problem,
$$ int_0^{2pi} log(1-2rcos theta +r^2) dtheta=2pi log^+(r^2) $$
I am curious whether there is any relationship between them.



And I got stuck on the proposition in the title. I found that
$$1-2frac{cos 2theta}{x^2}+frac{1}{x^4} =left(frac{1}{x}-e^{itheta}right)left(frac{1}{x}+e^{itheta}right)left(frac{1}{x}-e^{-itheta}right)left(frac{1}{x}+e^{-itheta}right)$$
But I couldn't move on.



Any hints? Thanks in advance.










share|cite|improve this question











$endgroup$





Prove $$int_0^infty log left(1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dx =2pi sin theta$$where $thetain[0,pi]$.




I've met another similar problem,
$$ int_0^{2pi} log(1-2rcos theta +r^2) dtheta=2pi log^+(r^2) $$
I am curious whether there is any relationship between them.



And I got stuck on the proposition in the title. I found that
$$1-2frac{cos 2theta}{x^2}+frac{1}{x^4} =left(frac{1}{x}-e^{itheta}right)left(frac{1}{x}+e^{itheta}right)left(frac{1}{x}-e^{-itheta}right)left(frac{1}{x}+e^{-itheta}right)$$
But I couldn't move on.



Any hints? Thanks in advance.







calculus integration trigonometry definite-integrals logarithms






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited Mar 11 at 12:18







Zero

















asked Mar 11 at 10:20









ZeroZero

49811




49811












  • $begingroup$
    Maybe you can complete a square and make a substitution afterwards.
    $endgroup$
    – mathreadler
    Mar 11 at 10:30






  • 1




    $begingroup$
    I am not sure about a relationship between them, but both of them can be solved by similar tehniques (Feynman's trick).
    $endgroup$
    – Zacky
    Mar 11 at 11:11


















  • $begingroup$
    Maybe you can complete a square and make a substitution afterwards.
    $endgroup$
    – mathreadler
    Mar 11 at 10:30






  • 1




    $begingroup$
    I am not sure about a relationship between them, but both of them can be solved by similar tehniques (Feynman's trick).
    $endgroup$
    – Zacky
    Mar 11 at 11:11
















$begingroup$
Maybe you can complete a square and make a substitution afterwards.
$endgroup$
– mathreadler
Mar 11 at 10:30




$begingroup$
Maybe you can complete a square and make a substitution afterwards.
$endgroup$
– mathreadler
Mar 11 at 10:30




1




1




$begingroup$
I am not sure about a relationship between them, but both of them can be solved by similar tehniques (Feynman's trick).
$endgroup$
– Zacky
Mar 11 at 11:11




$begingroup$
I am not sure about a relationship between them, but both of them can be solved by similar tehniques (Feynman's trick).
$endgroup$
– Zacky
Mar 11 at 11:11










3 Answers
3






active

oldest

votes


















7












$begingroup$

We start off by some $xrightarrow frac{1}{x}$ substitutions while derivating under the integral sign: $$I(theta)=int_0^infty log left(1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dxoverset{xrightarrow frac{1}{x}}=int_0^infty frac{ln(1- 2cos(2theta) x^2 +x^4)}{x^2}dx$$
$$I'(theta)=4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dxoverset{xrightarrow frac{1}{x}}=4int_0^infty frac{sin(2theta)x^2}{x^4-2cos(2theta)x^2+1}dx$$
Now summing up the two integrals from above gives us:
$$Rightarrow 2I'(theta)=4int_0^infty frac{sin(2theta)(1+x^2)}{x^4-2cos(2theta)x^2+1}dx=4int_0^infty frac{sin(2theta)left(frac{1}{x^2}+1right)}{x^2+frac{1}{x^2}-2cos(2theta)}dx$$
$$Rightarrow I'(theta)=2int_0^infty frac{sin(2theta)left(x-frac{1}{x}right)'}{left(x-frac{1}{x}right)^2 +2(1-cos(2theta))}dxoverset{large x- frac{1}{x}=t}=2int_{-infty}^infty frac{sin(2theta)}{t^2 +4sin^2 (theta)}dt$$
$$=2 frac{sin(2theta)}{2sin(theta)}arctanleft(frac{t}{2sin(theta)}right)bigg|_{-infty}^infty=2cos(theta) cdot pi$$
$$Rightarrow I(theta) = 2pi int cos(theta) dtheta =2pi sin theta +C$$
But $I(0)=0$ (see J.G. answer), thus:$$I(0)=0+CRightarrow C=0 Rightarrow boxed{I(theta)=2pisin(theta)}$$






share|cite|improve this answer











$endgroup$













  • $begingroup$
    Nice idea! But how to deal with $I'(0)$?
    $endgroup$
    – Zero
    Mar 11 at 12:50










  • $begingroup$
    Well, just plugg $theta =0$ here: $$4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dx$$
    $endgroup$
    – Zacky
    Mar 11 at 13:02












  • $begingroup$
    Sorry, I didn't understand. I thought if $theta=0$, it equals to $4int_0^infty frac{0}{(x^2-1)^2}dx$ , which is not integrable. Did I miss something?
    $endgroup$
    – Zero
    Mar 12 at 0:27










  • $begingroup$
    Wait, why doesn't it vanish after plugging $theta=0$?
    $endgroup$
    – Zacky
    Mar 12 at 12:24






  • 1




    $begingroup$
    Well, I found a method to avoid this problem. It's certain that $I'(theta)=2pi costheta$ for $theta in (0,2pi)$. Thus $I(theta)=2 pi sin theta+C$ for $theta in (0,2pi)$. Considering that $I(theta)$ is a continuous function on $[0,2pi]$, thus $I(theta)=2 pi sin theta+C$ for $theta in [0,2pi]$. Then from $I(0)=0$ we can arrive at the conclusion. I didn't understand what "plugging" means, maybe all I said is an obvious thing.
    $endgroup$
    – Zero
    yesterday



















5












$begingroup$

For $theta in [0;pi]$,
begin{align}
J(theta)&=int_0^infty lnleft(1-frac{2cos(2theta)}{x^2}+frac{1}{x^4}right) ,dx
end{align}

Perform the change of variable $y=dfrac{1}{x}$,



begin{align}
J(theta)&=int_0^infty frac{lnleft(1-2cos(2theta)x^2+x^4right)}{x^2} ,dx
end{align}



For $ageq -1$, define the function $F$ by,
begin{align}F(a)&=int_0^infty frac{lnleft(1+2ax^2+x^4right)}{x^2} ,dx\
&=left[-frac{lnleft(1+2ax^2+x^4right)}{x}right]_0^infty+int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
&=int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
end{align}

Perform the change of variable $y=dfrac{1}{x}$,
begin{align}F(a)&=int_0^infty frac{4left( frac{1}{x^2}+aright) }{x^2left(1+frac{2a}{x^2}+frac{1}{x^4}right) } ,dx\
&=int_0^infty frac{4left( 1+ax^2right) }{x^4+2ax^2+1 } ,dx\
end{align}

Therefore,
begin{align}F(a)&=int_0^infty frac{2(a+1)left( 1+x^2right) }{x^4+2ax^2+1 } ,dx\
&=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{x^2+frac{1}{x^2}+2a } ,dx\
&=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{left(x-frac{1}{x}right)^2+2(a+1) } ,dx\
end{align}

Perform the change of variable $y=x-dfrac{1}{x}$,
begin{align}F(a)&= 2(a+1)int_{-infty}^{+infty}frac{1}{x^2+2(a+1)},dx\
&=4(a+1)int_{0}^{+infty}frac{1}{x^2+2(a+1)},dx\
&=left[2sqrt{2(a+1)}arctanleft( frac{x}{sqrt{2(a+1)}} right)right]_0^infty\
&=boxed{pisqrt{2(1+a)}}
end{align}



Observe that, $J(theta)=Fbig(-cos(2theta)big)$.



begin{align} 2(1-cos(2theta))&=2(1-cos^2(theta)+sin^2 (theta))\
&=2times 2sin^2 (theta)\
&=4times sin^2 (theta)\
end{align}

Since, for $theta in [0;pi],sin(theta)geq 0$ then $sqrt{2(1-cos(2theta))}=2sin(theta)$



Therefore,
begin{align}boxed{J(theta)=2pi sin(theta)}end{align}






share|cite|improve this answer









$endgroup$





















    4












    $begingroup$

    To complement Zacky's answer I'll add a proof that $I(0)=0$. Applying $xmapstofrac{1}{x}$ for $xge 1$ gives $$I(x)=2int_0^inftyln|1-x^{-2}|dx=2int_0^1left[(1+frac{1}{x^2})ln(1-x^2)-2ln xright]\=-2int_0^1left[(1+x^2)sum_{nge 0}frac{x^{2n}}{n+1}+2ln xright]dx=-2int_0^1left[sum_{nge 0}left(frac{x^{2n}}{n+1}+frac{x^{2n+2}}{n+1}right)+2ln xright]dx\=-2left[sum_{nge 0}left(frac{x^{2n+1}}{(n+1)(2n+1)}+frac{x^{2n+3}}{(n+1)(2n+3)}right)+2xln x-2xright]_0^1\=-2left[sum_{nge 0}left(frac{4}{(2n+1)(2n+3)}right)-2right],$$which vanishes by partial fractions.






    share|cite|improve this answer









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      3 Answers
      3






      active

      oldest

      votes








      3 Answers
      3






      active

      oldest

      votes









      active

      oldest

      votes






      active

      oldest

      votes









      7












      $begingroup$

      We start off by some $xrightarrow frac{1}{x}$ substitutions while derivating under the integral sign: $$I(theta)=int_0^infty log left(1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dxoverset{xrightarrow frac{1}{x}}=int_0^infty frac{ln(1- 2cos(2theta) x^2 +x^4)}{x^2}dx$$
      $$I'(theta)=4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dxoverset{xrightarrow frac{1}{x}}=4int_0^infty frac{sin(2theta)x^2}{x^4-2cos(2theta)x^2+1}dx$$
      Now summing up the two integrals from above gives us:
      $$Rightarrow 2I'(theta)=4int_0^infty frac{sin(2theta)(1+x^2)}{x^4-2cos(2theta)x^2+1}dx=4int_0^infty frac{sin(2theta)left(frac{1}{x^2}+1right)}{x^2+frac{1}{x^2}-2cos(2theta)}dx$$
      $$Rightarrow I'(theta)=2int_0^infty frac{sin(2theta)left(x-frac{1}{x}right)'}{left(x-frac{1}{x}right)^2 +2(1-cos(2theta))}dxoverset{large x- frac{1}{x}=t}=2int_{-infty}^infty frac{sin(2theta)}{t^2 +4sin^2 (theta)}dt$$
      $$=2 frac{sin(2theta)}{2sin(theta)}arctanleft(frac{t}{2sin(theta)}right)bigg|_{-infty}^infty=2cos(theta) cdot pi$$
      $$Rightarrow I(theta) = 2pi int cos(theta) dtheta =2pi sin theta +C$$
      But $I(0)=0$ (see J.G. answer), thus:$$I(0)=0+CRightarrow C=0 Rightarrow boxed{I(theta)=2pisin(theta)}$$






      share|cite|improve this answer











      $endgroup$













      • $begingroup$
        Nice idea! But how to deal with $I'(0)$?
        $endgroup$
        – Zero
        Mar 11 at 12:50










      • $begingroup$
        Well, just plugg $theta =0$ here: $$4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dx$$
        $endgroup$
        – Zacky
        Mar 11 at 13:02












      • $begingroup$
        Sorry, I didn't understand. I thought if $theta=0$, it equals to $4int_0^infty frac{0}{(x^2-1)^2}dx$ , which is not integrable. Did I miss something?
        $endgroup$
        – Zero
        Mar 12 at 0:27










      • $begingroup$
        Wait, why doesn't it vanish after plugging $theta=0$?
        $endgroup$
        – Zacky
        Mar 12 at 12:24






      • 1




        $begingroup$
        Well, I found a method to avoid this problem. It's certain that $I'(theta)=2pi costheta$ for $theta in (0,2pi)$. Thus $I(theta)=2 pi sin theta+C$ for $theta in (0,2pi)$. Considering that $I(theta)$ is a continuous function on $[0,2pi]$, thus $I(theta)=2 pi sin theta+C$ for $theta in [0,2pi]$. Then from $I(0)=0$ we can arrive at the conclusion. I didn't understand what "plugging" means, maybe all I said is an obvious thing.
        $endgroup$
        – Zero
        yesterday
















      7












      $begingroup$

      We start off by some $xrightarrow frac{1}{x}$ substitutions while derivating under the integral sign: $$I(theta)=int_0^infty log left(1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dxoverset{xrightarrow frac{1}{x}}=int_0^infty frac{ln(1- 2cos(2theta) x^2 +x^4)}{x^2}dx$$
      $$I'(theta)=4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dxoverset{xrightarrow frac{1}{x}}=4int_0^infty frac{sin(2theta)x^2}{x^4-2cos(2theta)x^2+1}dx$$
      Now summing up the two integrals from above gives us:
      $$Rightarrow 2I'(theta)=4int_0^infty frac{sin(2theta)(1+x^2)}{x^4-2cos(2theta)x^2+1}dx=4int_0^infty frac{sin(2theta)left(frac{1}{x^2}+1right)}{x^2+frac{1}{x^2}-2cos(2theta)}dx$$
      $$Rightarrow I'(theta)=2int_0^infty frac{sin(2theta)left(x-frac{1}{x}right)'}{left(x-frac{1}{x}right)^2 +2(1-cos(2theta))}dxoverset{large x- frac{1}{x}=t}=2int_{-infty}^infty frac{sin(2theta)}{t^2 +4sin^2 (theta)}dt$$
      $$=2 frac{sin(2theta)}{2sin(theta)}arctanleft(frac{t}{2sin(theta)}right)bigg|_{-infty}^infty=2cos(theta) cdot pi$$
      $$Rightarrow I(theta) = 2pi int cos(theta) dtheta =2pi sin theta +C$$
      But $I(0)=0$ (see J.G. answer), thus:$$I(0)=0+CRightarrow C=0 Rightarrow boxed{I(theta)=2pisin(theta)}$$






      share|cite|improve this answer











      $endgroup$













      • $begingroup$
        Nice idea! But how to deal with $I'(0)$?
        $endgroup$
        – Zero
        Mar 11 at 12:50










      • $begingroup$
        Well, just plugg $theta =0$ here: $$4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dx$$
        $endgroup$
        – Zacky
        Mar 11 at 13:02












      • $begingroup$
        Sorry, I didn't understand. I thought if $theta=0$, it equals to $4int_0^infty frac{0}{(x^2-1)^2}dx$ , which is not integrable. Did I miss something?
        $endgroup$
        – Zero
        Mar 12 at 0:27










      • $begingroup$
        Wait, why doesn't it vanish after plugging $theta=0$?
        $endgroup$
        – Zacky
        Mar 12 at 12:24






      • 1




        $begingroup$
        Well, I found a method to avoid this problem. It's certain that $I'(theta)=2pi costheta$ for $theta in (0,2pi)$. Thus $I(theta)=2 pi sin theta+C$ for $theta in (0,2pi)$. Considering that $I(theta)$ is a continuous function on $[0,2pi]$, thus $I(theta)=2 pi sin theta+C$ for $theta in [0,2pi]$. Then from $I(0)=0$ we can arrive at the conclusion. I didn't understand what "plugging" means, maybe all I said is an obvious thing.
        $endgroup$
        – Zero
        yesterday














      7












      7








      7





      $begingroup$

      We start off by some $xrightarrow frac{1}{x}$ substitutions while derivating under the integral sign: $$I(theta)=int_0^infty log left(1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dxoverset{xrightarrow frac{1}{x}}=int_0^infty frac{ln(1- 2cos(2theta) x^2 +x^4)}{x^2}dx$$
      $$I'(theta)=4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dxoverset{xrightarrow frac{1}{x}}=4int_0^infty frac{sin(2theta)x^2}{x^4-2cos(2theta)x^2+1}dx$$
      Now summing up the two integrals from above gives us:
      $$Rightarrow 2I'(theta)=4int_0^infty frac{sin(2theta)(1+x^2)}{x^4-2cos(2theta)x^2+1}dx=4int_0^infty frac{sin(2theta)left(frac{1}{x^2}+1right)}{x^2+frac{1}{x^2}-2cos(2theta)}dx$$
      $$Rightarrow I'(theta)=2int_0^infty frac{sin(2theta)left(x-frac{1}{x}right)'}{left(x-frac{1}{x}right)^2 +2(1-cos(2theta))}dxoverset{large x- frac{1}{x}=t}=2int_{-infty}^infty frac{sin(2theta)}{t^2 +4sin^2 (theta)}dt$$
      $$=2 frac{sin(2theta)}{2sin(theta)}arctanleft(frac{t}{2sin(theta)}right)bigg|_{-infty}^infty=2cos(theta) cdot pi$$
      $$Rightarrow I(theta) = 2pi int cos(theta) dtheta =2pi sin theta +C$$
      But $I(0)=0$ (see J.G. answer), thus:$$I(0)=0+CRightarrow C=0 Rightarrow boxed{I(theta)=2pisin(theta)}$$






      share|cite|improve this answer











      $endgroup$



      We start off by some $xrightarrow frac{1}{x}$ substitutions while derivating under the integral sign: $$I(theta)=int_0^infty log left(1-2frac{cos 2theta}{x^2}+frac{1}{x^4} right)dxoverset{xrightarrow frac{1}{x}}=int_0^infty frac{ln(1- 2cos(2theta) x^2 +x^4)}{x^2}dx$$
      $$I'(theta)=4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dxoverset{xrightarrow frac{1}{x}}=4int_0^infty frac{sin(2theta)x^2}{x^4-2cos(2theta)x^2+1}dx$$
      Now summing up the two integrals from above gives us:
      $$Rightarrow 2I'(theta)=4int_0^infty frac{sin(2theta)(1+x^2)}{x^4-2cos(2theta)x^2+1}dx=4int_0^infty frac{sin(2theta)left(frac{1}{x^2}+1right)}{x^2+frac{1}{x^2}-2cos(2theta)}dx$$
      $$Rightarrow I'(theta)=2int_0^infty frac{sin(2theta)left(x-frac{1}{x}right)'}{left(x-frac{1}{x}right)^2 +2(1-cos(2theta))}dxoverset{large x- frac{1}{x}=t}=2int_{-infty}^infty frac{sin(2theta)}{t^2 +4sin^2 (theta)}dt$$
      $$=2 frac{sin(2theta)}{2sin(theta)}arctanleft(frac{t}{2sin(theta)}right)bigg|_{-infty}^infty=2cos(theta) cdot pi$$
      $$Rightarrow I(theta) = 2pi int cos(theta) dtheta =2pi sin theta +C$$
      But $I(0)=0$ (see J.G. answer), thus:$$I(0)=0+CRightarrow C=0 Rightarrow boxed{I(theta)=2pisin(theta)}$$







      share|cite|improve this answer














      share|cite|improve this answer



      share|cite|improve this answer








      edited Mar 11 at 11:23

























      answered Mar 11 at 11:01









      ZackyZacky

      7,76011061




      7,76011061












      • $begingroup$
        Nice idea! But how to deal with $I'(0)$?
        $endgroup$
        – Zero
        Mar 11 at 12:50










      • $begingroup$
        Well, just plugg $theta =0$ here: $$4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dx$$
        $endgroup$
        – Zacky
        Mar 11 at 13:02












      • $begingroup$
        Sorry, I didn't understand. I thought if $theta=0$, it equals to $4int_0^infty frac{0}{(x^2-1)^2}dx$ , which is not integrable. Did I miss something?
        $endgroup$
        – Zero
        Mar 12 at 0:27










      • $begingroup$
        Wait, why doesn't it vanish after plugging $theta=0$?
        $endgroup$
        – Zacky
        Mar 12 at 12:24






      • 1




        $begingroup$
        Well, I found a method to avoid this problem. It's certain that $I'(theta)=2pi costheta$ for $theta in (0,2pi)$. Thus $I(theta)=2 pi sin theta+C$ for $theta in (0,2pi)$. Considering that $I(theta)$ is a continuous function on $[0,2pi]$, thus $I(theta)=2 pi sin theta+C$ for $theta in [0,2pi]$. Then from $I(0)=0$ we can arrive at the conclusion. I didn't understand what "plugging" means, maybe all I said is an obvious thing.
        $endgroup$
        – Zero
        yesterday


















      • $begingroup$
        Nice idea! But how to deal with $I'(0)$?
        $endgroup$
        – Zero
        Mar 11 at 12:50










      • $begingroup$
        Well, just plugg $theta =0$ here: $$4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dx$$
        $endgroup$
        – Zacky
        Mar 11 at 13:02












      • $begingroup$
        Sorry, I didn't understand. I thought if $theta=0$, it equals to $4int_0^infty frac{0}{(x^2-1)^2}dx$ , which is not integrable. Did I miss something?
        $endgroup$
        – Zero
        Mar 12 at 0:27










      • $begingroup$
        Wait, why doesn't it vanish after plugging $theta=0$?
        $endgroup$
        – Zacky
        Mar 12 at 12:24






      • 1




        $begingroup$
        Well, I found a method to avoid this problem. It's certain that $I'(theta)=2pi costheta$ for $theta in (0,2pi)$. Thus $I(theta)=2 pi sin theta+C$ for $theta in (0,2pi)$. Considering that $I(theta)$ is a continuous function on $[0,2pi]$, thus $I(theta)=2 pi sin theta+C$ for $theta in [0,2pi]$. Then from $I(0)=0$ we can arrive at the conclusion. I didn't understand what "plugging" means, maybe all I said is an obvious thing.
        $endgroup$
        – Zero
        yesterday
















      $begingroup$
      Nice idea! But how to deal with $I'(0)$?
      $endgroup$
      – Zero
      Mar 11 at 12:50




      $begingroup$
      Nice idea! But how to deal with $I'(0)$?
      $endgroup$
      – Zero
      Mar 11 at 12:50












      $begingroup$
      Well, just plugg $theta =0$ here: $$4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dx$$
      $endgroup$
      – Zacky
      Mar 11 at 13:02






      $begingroup$
      Well, just plugg $theta =0$ here: $$4int_0^infty frac{sin(2theta)}{x^4-2cos(2theta)x^2+1}dx$$
      $endgroup$
      – Zacky
      Mar 11 at 13:02














      $begingroup$
      Sorry, I didn't understand. I thought if $theta=0$, it equals to $4int_0^infty frac{0}{(x^2-1)^2}dx$ , which is not integrable. Did I miss something?
      $endgroup$
      – Zero
      Mar 12 at 0:27




      $begingroup$
      Sorry, I didn't understand. I thought if $theta=0$, it equals to $4int_0^infty frac{0}{(x^2-1)^2}dx$ , which is not integrable. Did I miss something?
      $endgroup$
      – Zero
      Mar 12 at 0:27












      $begingroup$
      Wait, why doesn't it vanish after plugging $theta=0$?
      $endgroup$
      – Zacky
      Mar 12 at 12:24




      $begingroup$
      Wait, why doesn't it vanish after plugging $theta=0$?
      $endgroup$
      – Zacky
      Mar 12 at 12:24




      1




      1




      $begingroup$
      Well, I found a method to avoid this problem. It's certain that $I'(theta)=2pi costheta$ for $theta in (0,2pi)$. Thus $I(theta)=2 pi sin theta+C$ for $theta in (0,2pi)$. Considering that $I(theta)$ is a continuous function on $[0,2pi]$, thus $I(theta)=2 pi sin theta+C$ for $theta in [0,2pi]$. Then from $I(0)=0$ we can arrive at the conclusion. I didn't understand what "plugging" means, maybe all I said is an obvious thing.
      $endgroup$
      – Zero
      yesterday




      $begingroup$
      Well, I found a method to avoid this problem. It's certain that $I'(theta)=2pi costheta$ for $theta in (0,2pi)$. Thus $I(theta)=2 pi sin theta+C$ for $theta in (0,2pi)$. Considering that $I(theta)$ is a continuous function on $[0,2pi]$, thus $I(theta)=2 pi sin theta+C$ for $theta in [0,2pi]$. Then from $I(0)=0$ we can arrive at the conclusion. I didn't understand what "plugging" means, maybe all I said is an obvious thing.
      $endgroup$
      – Zero
      yesterday











      5












      $begingroup$

      For $theta in [0;pi]$,
      begin{align}
      J(theta)&=int_0^infty lnleft(1-frac{2cos(2theta)}{x^2}+frac{1}{x^4}right) ,dx
      end{align}

      Perform the change of variable $y=dfrac{1}{x}$,



      begin{align}
      J(theta)&=int_0^infty frac{lnleft(1-2cos(2theta)x^2+x^4right)}{x^2} ,dx
      end{align}



      For $ageq -1$, define the function $F$ by,
      begin{align}F(a)&=int_0^infty frac{lnleft(1+2ax^2+x^4right)}{x^2} ,dx\
      &=left[-frac{lnleft(1+2ax^2+x^4right)}{x}right]_0^infty+int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
      &=int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
      end{align}

      Perform the change of variable $y=dfrac{1}{x}$,
      begin{align}F(a)&=int_0^infty frac{4left( frac{1}{x^2}+aright) }{x^2left(1+frac{2a}{x^2}+frac{1}{x^4}right) } ,dx\
      &=int_0^infty frac{4left( 1+ax^2right) }{x^4+2ax^2+1 } ,dx\
      end{align}

      Therefore,
      begin{align}F(a)&=int_0^infty frac{2(a+1)left( 1+x^2right) }{x^4+2ax^2+1 } ,dx\
      &=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{x^2+frac{1}{x^2}+2a } ,dx\
      &=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{left(x-frac{1}{x}right)^2+2(a+1) } ,dx\
      end{align}

      Perform the change of variable $y=x-dfrac{1}{x}$,
      begin{align}F(a)&= 2(a+1)int_{-infty}^{+infty}frac{1}{x^2+2(a+1)},dx\
      &=4(a+1)int_{0}^{+infty}frac{1}{x^2+2(a+1)},dx\
      &=left[2sqrt{2(a+1)}arctanleft( frac{x}{sqrt{2(a+1)}} right)right]_0^infty\
      &=boxed{pisqrt{2(1+a)}}
      end{align}



      Observe that, $J(theta)=Fbig(-cos(2theta)big)$.



      begin{align} 2(1-cos(2theta))&=2(1-cos^2(theta)+sin^2 (theta))\
      &=2times 2sin^2 (theta)\
      &=4times sin^2 (theta)\
      end{align}

      Since, for $theta in [0;pi],sin(theta)geq 0$ then $sqrt{2(1-cos(2theta))}=2sin(theta)$



      Therefore,
      begin{align}boxed{J(theta)=2pi sin(theta)}end{align}






      share|cite|improve this answer









      $endgroup$


















        5












        $begingroup$

        For $theta in [0;pi]$,
        begin{align}
        J(theta)&=int_0^infty lnleft(1-frac{2cos(2theta)}{x^2}+frac{1}{x^4}right) ,dx
        end{align}

        Perform the change of variable $y=dfrac{1}{x}$,



        begin{align}
        J(theta)&=int_0^infty frac{lnleft(1-2cos(2theta)x^2+x^4right)}{x^2} ,dx
        end{align}



        For $ageq -1$, define the function $F$ by,
        begin{align}F(a)&=int_0^infty frac{lnleft(1+2ax^2+x^4right)}{x^2} ,dx\
        &=left[-frac{lnleft(1+2ax^2+x^4right)}{x}right]_0^infty+int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
        &=int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
        end{align}

        Perform the change of variable $y=dfrac{1}{x}$,
        begin{align}F(a)&=int_0^infty frac{4left( frac{1}{x^2}+aright) }{x^2left(1+frac{2a}{x^2}+frac{1}{x^4}right) } ,dx\
        &=int_0^infty frac{4left( 1+ax^2right) }{x^4+2ax^2+1 } ,dx\
        end{align}

        Therefore,
        begin{align}F(a)&=int_0^infty frac{2(a+1)left( 1+x^2right) }{x^4+2ax^2+1 } ,dx\
        &=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{x^2+frac{1}{x^2}+2a } ,dx\
        &=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{left(x-frac{1}{x}right)^2+2(a+1) } ,dx\
        end{align}

        Perform the change of variable $y=x-dfrac{1}{x}$,
        begin{align}F(a)&= 2(a+1)int_{-infty}^{+infty}frac{1}{x^2+2(a+1)},dx\
        &=4(a+1)int_{0}^{+infty}frac{1}{x^2+2(a+1)},dx\
        &=left[2sqrt{2(a+1)}arctanleft( frac{x}{sqrt{2(a+1)}} right)right]_0^infty\
        &=boxed{pisqrt{2(1+a)}}
        end{align}



        Observe that, $J(theta)=Fbig(-cos(2theta)big)$.



        begin{align} 2(1-cos(2theta))&=2(1-cos^2(theta)+sin^2 (theta))\
        &=2times 2sin^2 (theta)\
        &=4times sin^2 (theta)\
        end{align}

        Since, for $theta in [0;pi],sin(theta)geq 0$ then $sqrt{2(1-cos(2theta))}=2sin(theta)$



        Therefore,
        begin{align}boxed{J(theta)=2pi sin(theta)}end{align}






        share|cite|improve this answer









        $endgroup$
















          5












          5








          5





          $begingroup$

          For $theta in [0;pi]$,
          begin{align}
          J(theta)&=int_0^infty lnleft(1-frac{2cos(2theta)}{x^2}+frac{1}{x^4}right) ,dx
          end{align}

          Perform the change of variable $y=dfrac{1}{x}$,



          begin{align}
          J(theta)&=int_0^infty frac{lnleft(1-2cos(2theta)x^2+x^4right)}{x^2} ,dx
          end{align}



          For $ageq -1$, define the function $F$ by,
          begin{align}F(a)&=int_0^infty frac{lnleft(1+2ax^2+x^4right)}{x^2} ,dx\
          &=left[-frac{lnleft(1+2ax^2+x^4right)}{x}right]_0^infty+int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
          &=int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
          end{align}

          Perform the change of variable $y=dfrac{1}{x}$,
          begin{align}F(a)&=int_0^infty frac{4left( frac{1}{x^2}+aright) }{x^2left(1+frac{2a}{x^2}+frac{1}{x^4}right) } ,dx\
          &=int_0^infty frac{4left( 1+ax^2right) }{x^4+2ax^2+1 } ,dx\
          end{align}

          Therefore,
          begin{align}F(a)&=int_0^infty frac{2(a+1)left( 1+x^2right) }{x^4+2ax^2+1 } ,dx\
          &=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{x^2+frac{1}{x^2}+2a } ,dx\
          &=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{left(x-frac{1}{x}right)^2+2(a+1) } ,dx\
          end{align}

          Perform the change of variable $y=x-dfrac{1}{x}$,
          begin{align}F(a)&= 2(a+1)int_{-infty}^{+infty}frac{1}{x^2+2(a+1)},dx\
          &=4(a+1)int_{0}^{+infty}frac{1}{x^2+2(a+1)},dx\
          &=left[2sqrt{2(a+1)}arctanleft( frac{x}{sqrt{2(a+1)}} right)right]_0^infty\
          &=boxed{pisqrt{2(1+a)}}
          end{align}



          Observe that, $J(theta)=Fbig(-cos(2theta)big)$.



          begin{align} 2(1-cos(2theta))&=2(1-cos^2(theta)+sin^2 (theta))\
          &=2times 2sin^2 (theta)\
          &=4times sin^2 (theta)\
          end{align}

          Since, for $theta in [0;pi],sin(theta)geq 0$ then $sqrt{2(1-cos(2theta))}=2sin(theta)$



          Therefore,
          begin{align}boxed{J(theta)=2pi sin(theta)}end{align}






          share|cite|improve this answer









          $endgroup$



          For $theta in [0;pi]$,
          begin{align}
          J(theta)&=int_0^infty lnleft(1-frac{2cos(2theta)}{x^2}+frac{1}{x^4}right) ,dx
          end{align}

          Perform the change of variable $y=dfrac{1}{x}$,



          begin{align}
          J(theta)&=int_0^infty frac{lnleft(1-2cos(2theta)x^2+x^4right)}{x^2} ,dx
          end{align}



          For $ageq -1$, define the function $F$ by,
          begin{align}F(a)&=int_0^infty frac{lnleft(1+2ax^2+x^4right)}{x^2} ,dx\
          &=left[-frac{lnleft(1+2ax^2+x^4right)}{x}right]_0^infty+int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
          &=int_0^infty frac{4left(x^2+aright)}{1+2ax^2+x^4},dx\
          end{align}

          Perform the change of variable $y=dfrac{1}{x}$,
          begin{align}F(a)&=int_0^infty frac{4left( frac{1}{x^2}+aright) }{x^2left(1+frac{2a}{x^2}+frac{1}{x^4}right) } ,dx\
          &=int_0^infty frac{4left( 1+ax^2right) }{x^4+2ax^2+1 } ,dx\
          end{align}

          Therefore,
          begin{align}F(a)&=int_0^infty frac{2(a+1)left( 1+x^2right) }{x^4+2ax^2+1 } ,dx\
          &=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{x^2+frac{1}{x^2}+2a } ,dx\
          &=2(a+1)int_0^infty frac{left(1+frac{1}{x^2}right)}{left(x-frac{1}{x}right)^2+2(a+1) } ,dx\
          end{align}

          Perform the change of variable $y=x-dfrac{1}{x}$,
          begin{align}F(a)&= 2(a+1)int_{-infty}^{+infty}frac{1}{x^2+2(a+1)},dx\
          &=4(a+1)int_{0}^{+infty}frac{1}{x^2+2(a+1)},dx\
          &=left[2sqrt{2(a+1)}arctanleft( frac{x}{sqrt{2(a+1)}} right)right]_0^infty\
          &=boxed{pisqrt{2(1+a)}}
          end{align}



          Observe that, $J(theta)=Fbig(-cos(2theta)big)$.



          begin{align} 2(1-cos(2theta))&=2(1-cos^2(theta)+sin^2 (theta))\
          &=2times 2sin^2 (theta)\
          &=4times sin^2 (theta)\
          end{align}

          Since, for $theta in [0;pi],sin(theta)geq 0$ then $sqrt{2(1-cos(2theta))}=2sin(theta)$



          Therefore,
          begin{align}boxed{J(theta)=2pi sin(theta)}end{align}







          share|cite|improve this answer












          share|cite|improve this answer



          share|cite|improve this answer










          answered Mar 11 at 19:49









          FDPFDP

          6,17211829




          6,17211829























              4












              $begingroup$

              To complement Zacky's answer I'll add a proof that $I(0)=0$. Applying $xmapstofrac{1}{x}$ for $xge 1$ gives $$I(x)=2int_0^inftyln|1-x^{-2}|dx=2int_0^1left[(1+frac{1}{x^2})ln(1-x^2)-2ln xright]\=-2int_0^1left[(1+x^2)sum_{nge 0}frac{x^{2n}}{n+1}+2ln xright]dx=-2int_0^1left[sum_{nge 0}left(frac{x^{2n}}{n+1}+frac{x^{2n+2}}{n+1}right)+2ln xright]dx\=-2left[sum_{nge 0}left(frac{x^{2n+1}}{(n+1)(2n+1)}+frac{x^{2n+3}}{(n+1)(2n+3)}right)+2xln x-2xright]_0^1\=-2left[sum_{nge 0}left(frac{4}{(2n+1)(2n+3)}right)-2right],$$which vanishes by partial fractions.






              share|cite|improve this answer









              $endgroup$


















                4












                $begingroup$

                To complement Zacky's answer I'll add a proof that $I(0)=0$. Applying $xmapstofrac{1}{x}$ for $xge 1$ gives $$I(x)=2int_0^inftyln|1-x^{-2}|dx=2int_0^1left[(1+frac{1}{x^2})ln(1-x^2)-2ln xright]\=-2int_0^1left[(1+x^2)sum_{nge 0}frac{x^{2n}}{n+1}+2ln xright]dx=-2int_0^1left[sum_{nge 0}left(frac{x^{2n}}{n+1}+frac{x^{2n+2}}{n+1}right)+2ln xright]dx\=-2left[sum_{nge 0}left(frac{x^{2n+1}}{(n+1)(2n+1)}+frac{x^{2n+3}}{(n+1)(2n+3)}right)+2xln x-2xright]_0^1\=-2left[sum_{nge 0}left(frac{4}{(2n+1)(2n+3)}right)-2right],$$which vanishes by partial fractions.






                share|cite|improve this answer









                $endgroup$
















                  4












                  4








                  4





                  $begingroup$

                  To complement Zacky's answer I'll add a proof that $I(0)=0$. Applying $xmapstofrac{1}{x}$ for $xge 1$ gives $$I(x)=2int_0^inftyln|1-x^{-2}|dx=2int_0^1left[(1+frac{1}{x^2})ln(1-x^2)-2ln xright]\=-2int_0^1left[(1+x^2)sum_{nge 0}frac{x^{2n}}{n+1}+2ln xright]dx=-2int_0^1left[sum_{nge 0}left(frac{x^{2n}}{n+1}+frac{x^{2n+2}}{n+1}right)+2ln xright]dx\=-2left[sum_{nge 0}left(frac{x^{2n+1}}{(n+1)(2n+1)}+frac{x^{2n+3}}{(n+1)(2n+3)}right)+2xln x-2xright]_0^1\=-2left[sum_{nge 0}left(frac{4}{(2n+1)(2n+3)}right)-2right],$$which vanishes by partial fractions.






                  share|cite|improve this answer









                  $endgroup$



                  To complement Zacky's answer I'll add a proof that $I(0)=0$. Applying $xmapstofrac{1}{x}$ for $xge 1$ gives $$I(x)=2int_0^inftyln|1-x^{-2}|dx=2int_0^1left[(1+frac{1}{x^2})ln(1-x^2)-2ln xright]\=-2int_0^1left[(1+x^2)sum_{nge 0}frac{x^{2n}}{n+1}+2ln xright]dx=-2int_0^1left[sum_{nge 0}left(frac{x^{2n}}{n+1}+frac{x^{2n+2}}{n+1}right)+2ln xright]dx\=-2left[sum_{nge 0}left(frac{x^{2n+1}}{(n+1)(2n+1)}+frac{x^{2n+3}}{(n+1)(2n+3)}right)+2xln x-2xright]_0^1\=-2left[sum_{nge 0}left(frac{4}{(2n+1)(2n+3)}right)-2right],$$which vanishes by partial fractions.







                  share|cite|improve this answer












                  share|cite|improve this answer



                  share|cite|improve this answer










                  answered Mar 11 at 11:08









                  J.G.J.G.

                  30.3k23148




                  30.3k23148






























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                      Where did Arya get these scars? Unicorn Meta Zoo #1: Why another podcast? Announcing the arrival of Valued Associate #679: Cesar Manara Favourite questions and answers from the 1st quarter of 2019Why did Arya refuse to end it?Has the pronunciation of Arya Stark's name changed?Has Arya forgiven people?Why did Arya Stark lose her vision?Why can Arya still use the faces?Has the Narrow Sea become narrower?Does Arya Stark know how to make poisons outside of the House of Black and White?Why did Nymeria leave Arya?Why did Arya not kill the Lannister soldiers she encountered in the Riverlands?What is the current canonical age of Sansa, Bran and Arya Stark?