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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