Tricky real integral











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I'm trying to prove the following:
$$ int_0^{2 pi} e^{cos(2 t)} cos(sin(2 t)) =2pi $$



Numerical analysis agrees with this to very high accuracy, so I'm almost sure it's true. Mathematica gives this answer after thinking for a long, but gives an insane antiderivative in terms of exponential integrals. I'd like to evaluate the integral with purely real methods (I've never done complex analysis), as elegantly as possible.



How can I tackle this integral?










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  • 1




    Have you heard of Cauchy integral theorem?
    – Frank W.
    2 hours ago










  • It would appear that$$int_0^{2pi}e^{cos at}cos(sin at),mathrm dt=2pi$$at least for all non-zero integer values of $a$.
    – user170231
    2 hours ago












  • $x=cos(2t)$ then $dx=-2sin(2t)dt$ and the integral has to be broken up into four parts at intervals with $t=frac{pi}{2}$, each with integrand $frac{1}{2}e^xcos(x)$. Each piece should integrate to $frac{pi}{2}$.
    – herb steinberg
    1 hour ago















up vote
2
down vote

favorite
1












I'm trying to prove the following:
$$ int_0^{2 pi} e^{cos(2 t)} cos(sin(2 t)) =2pi $$



Numerical analysis agrees with this to very high accuracy, so I'm almost sure it's true. Mathematica gives this answer after thinking for a long, but gives an insane antiderivative in terms of exponential integrals. I'd like to evaluate the integral with purely real methods (I've never done complex analysis), as elegantly as possible.



How can I tackle this integral?










share|cite|improve this question


















  • 1




    Have you heard of Cauchy integral theorem?
    – Frank W.
    2 hours ago










  • It would appear that$$int_0^{2pi}e^{cos at}cos(sin at),mathrm dt=2pi$$at least for all non-zero integer values of $a$.
    – user170231
    2 hours ago












  • $x=cos(2t)$ then $dx=-2sin(2t)dt$ and the integral has to be broken up into four parts at intervals with $t=frac{pi}{2}$, each with integrand $frac{1}{2}e^xcos(x)$. Each piece should integrate to $frac{pi}{2}$.
    – herb steinberg
    1 hour ago













up vote
2
down vote

favorite
1









up vote
2
down vote

favorite
1






1





I'm trying to prove the following:
$$ int_0^{2 pi} e^{cos(2 t)} cos(sin(2 t)) =2pi $$



Numerical analysis agrees with this to very high accuracy, so I'm almost sure it's true. Mathematica gives this answer after thinking for a long, but gives an insane antiderivative in terms of exponential integrals. I'd like to evaluate the integral with purely real methods (I've never done complex analysis), as elegantly as possible.



How can I tackle this integral?










share|cite|improve this question













I'm trying to prove the following:
$$ int_0^{2 pi} e^{cos(2 t)} cos(sin(2 t)) =2pi $$



Numerical analysis agrees with this to very high accuracy, so I'm almost sure it's true. Mathematica gives this answer after thinking for a long, but gives an insane antiderivative in terms of exponential integrals. I'd like to evaluate the integral with purely real methods (I've never done complex analysis), as elegantly as possible.



How can I tackle this integral?







calculus integration definite-integrals






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asked 2 hours ago









NMister

343110




343110








  • 1




    Have you heard of Cauchy integral theorem?
    – Frank W.
    2 hours ago










  • It would appear that$$int_0^{2pi}e^{cos at}cos(sin at),mathrm dt=2pi$$at least for all non-zero integer values of $a$.
    – user170231
    2 hours ago












  • $x=cos(2t)$ then $dx=-2sin(2t)dt$ and the integral has to be broken up into four parts at intervals with $t=frac{pi}{2}$, each with integrand $frac{1}{2}e^xcos(x)$. Each piece should integrate to $frac{pi}{2}$.
    – herb steinberg
    1 hour ago














  • 1




    Have you heard of Cauchy integral theorem?
    – Frank W.
    2 hours ago










  • It would appear that$$int_0^{2pi}e^{cos at}cos(sin at),mathrm dt=2pi$$at least for all non-zero integer values of $a$.
    – user170231
    2 hours ago












  • $x=cos(2t)$ then $dx=-2sin(2t)dt$ and the integral has to be broken up into four parts at intervals with $t=frac{pi}{2}$, each with integrand $frac{1}{2}e^xcos(x)$. Each piece should integrate to $frac{pi}{2}$.
    – herb steinberg
    1 hour ago








1




1




Have you heard of Cauchy integral theorem?
– Frank W.
2 hours ago




Have you heard of Cauchy integral theorem?
– Frank W.
2 hours ago












It would appear that$$int_0^{2pi}e^{cos at}cos(sin at),mathrm dt=2pi$$at least for all non-zero integer values of $a$.
– user170231
2 hours ago






It would appear that$$int_0^{2pi}e^{cos at}cos(sin at),mathrm dt=2pi$$at least for all non-zero integer values of $a$.
– user170231
2 hours ago














$x=cos(2t)$ then $dx=-2sin(2t)dt$ and the integral has to be broken up into four parts at intervals with $t=frac{pi}{2}$, each with integrand $frac{1}{2}e^xcos(x)$. Each piece should integrate to $frac{pi}{2}$.
– herb steinberg
1 hour ago




$x=cos(2t)$ then $dx=-2sin(2t)dt$ and the integral has to be broken up into four parts at intervals with $t=frac{pi}{2}$, each with integrand $frac{1}{2}e^xcos(x)$. Each piece should integrate to $frac{pi}{2}$.
– herb steinberg
1 hour ago










1 Answer
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Write



$$ I(alpha) = int_{0}^{2pi} e^{alpha cos(2t)}cos(alpha sin(2t)) , dt. $$



Then $I(0) = 2pi$, and for $alpha > 0$,



begin{align*}
I'(alpha)
&= int_{0}^{2pi} left[ e^{alpha cos(2t)}cos(alpha sin(2t))cos(2t) - e^{alpha cos(2t)}sin(alpha sin(2t))sin(2t) right] , dt \
&= left[ frac{1}{2alpha} e^{alphacos(2t)}sin(alphasin(2t)) right]_{0}^{2pi} \
&= 0.
end{align*}



So $I(alpha) = 2pi$ for all $alpha in mathbb{R}$.





A general computation. Let $f$ be analytic on $B(0,R)$. Define $I : [0, R) to mathbb{C}$ by



$$ I(r) = int_{0}^{2pi} f(re^{itheta}) , dtheta. $$



Then



$$ I'(r)
= int_{0}^{2pi} f'(re^{itheta})e^{itheta} , dtheta
= left[ frac{1}{ir} f(re^{itheta}) right]_{0}^{2pi}
= 0 $$



and thus $I$ is constant with the value $I(0) = 2pi f(0)$. The above answer corresponds to the real part of this computation with $f(z) = e^z$.






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    1 Answer
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    1 Answer
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    up vote
    6
    down vote













    Write



    $$ I(alpha) = int_{0}^{2pi} e^{alpha cos(2t)}cos(alpha sin(2t)) , dt. $$



    Then $I(0) = 2pi$, and for $alpha > 0$,



    begin{align*}
    I'(alpha)
    &= int_{0}^{2pi} left[ e^{alpha cos(2t)}cos(alpha sin(2t))cos(2t) - e^{alpha cos(2t)}sin(alpha sin(2t))sin(2t) right] , dt \
    &= left[ frac{1}{2alpha} e^{alphacos(2t)}sin(alphasin(2t)) right]_{0}^{2pi} \
    &= 0.
    end{align*}



    So $I(alpha) = 2pi$ for all $alpha in mathbb{R}$.





    A general computation. Let $f$ be analytic on $B(0,R)$. Define $I : [0, R) to mathbb{C}$ by



    $$ I(r) = int_{0}^{2pi} f(re^{itheta}) , dtheta. $$



    Then



    $$ I'(r)
    = int_{0}^{2pi} f'(re^{itheta})e^{itheta} , dtheta
    = left[ frac{1}{ir} f(re^{itheta}) right]_{0}^{2pi}
    = 0 $$



    and thus $I$ is constant with the value $I(0) = 2pi f(0)$. The above answer corresponds to the real part of this computation with $f(z) = e^z$.






    share|cite|improve this answer



























      up vote
      6
      down vote













      Write



      $$ I(alpha) = int_{0}^{2pi} e^{alpha cos(2t)}cos(alpha sin(2t)) , dt. $$



      Then $I(0) = 2pi$, and for $alpha > 0$,



      begin{align*}
      I'(alpha)
      &= int_{0}^{2pi} left[ e^{alpha cos(2t)}cos(alpha sin(2t))cos(2t) - e^{alpha cos(2t)}sin(alpha sin(2t))sin(2t) right] , dt \
      &= left[ frac{1}{2alpha} e^{alphacos(2t)}sin(alphasin(2t)) right]_{0}^{2pi} \
      &= 0.
      end{align*}



      So $I(alpha) = 2pi$ for all $alpha in mathbb{R}$.





      A general computation. Let $f$ be analytic on $B(0,R)$. Define $I : [0, R) to mathbb{C}$ by



      $$ I(r) = int_{0}^{2pi} f(re^{itheta}) , dtheta. $$



      Then



      $$ I'(r)
      = int_{0}^{2pi} f'(re^{itheta})e^{itheta} , dtheta
      = left[ frac{1}{ir} f(re^{itheta}) right]_{0}^{2pi}
      = 0 $$



      and thus $I$ is constant with the value $I(0) = 2pi f(0)$. The above answer corresponds to the real part of this computation with $f(z) = e^z$.






      share|cite|improve this answer

























        up vote
        6
        down vote










        up vote
        6
        down vote









        Write



        $$ I(alpha) = int_{0}^{2pi} e^{alpha cos(2t)}cos(alpha sin(2t)) , dt. $$



        Then $I(0) = 2pi$, and for $alpha > 0$,



        begin{align*}
        I'(alpha)
        &= int_{0}^{2pi} left[ e^{alpha cos(2t)}cos(alpha sin(2t))cos(2t) - e^{alpha cos(2t)}sin(alpha sin(2t))sin(2t) right] , dt \
        &= left[ frac{1}{2alpha} e^{alphacos(2t)}sin(alphasin(2t)) right]_{0}^{2pi} \
        &= 0.
        end{align*}



        So $I(alpha) = 2pi$ for all $alpha in mathbb{R}$.





        A general computation. Let $f$ be analytic on $B(0,R)$. Define $I : [0, R) to mathbb{C}$ by



        $$ I(r) = int_{0}^{2pi} f(re^{itheta}) , dtheta. $$



        Then



        $$ I'(r)
        = int_{0}^{2pi} f'(re^{itheta})e^{itheta} , dtheta
        = left[ frac{1}{ir} f(re^{itheta}) right]_{0}^{2pi}
        = 0 $$



        and thus $I$ is constant with the value $I(0) = 2pi f(0)$. The above answer corresponds to the real part of this computation with $f(z) = e^z$.






        share|cite|improve this answer














        Write



        $$ I(alpha) = int_{0}^{2pi} e^{alpha cos(2t)}cos(alpha sin(2t)) , dt. $$



        Then $I(0) = 2pi$, and for $alpha > 0$,



        begin{align*}
        I'(alpha)
        &= int_{0}^{2pi} left[ e^{alpha cos(2t)}cos(alpha sin(2t))cos(2t) - e^{alpha cos(2t)}sin(alpha sin(2t))sin(2t) right] , dt \
        &= left[ frac{1}{2alpha} e^{alphacos(2t)}sin(alphasin(2t)) right]_{0}^{2pi} \
        &= 0.
        end{align*}



        So $I(alpha) = 2pi$ for all $alpha in mathbb{R}$.





        A general computation. Let $f$ be analytic on $B(0,R)$. Define $I : [0, R) to mathbb{C}$ by



        $$ I(r) = int_{0}^{2pi} f(re^{itheta}) , dtheta. $$



        Then



        $$ I'(r)
        = int_{0}^{2pi} f'(re^{itheta})e^{itheta} , dtheta
        = left[ frac{1}{ir} f(re^{itheta}) right]_{0}^{2pi}
        = 0 $$



        and thus $I$ is constant with the value $I(0) = 2pi f(0)$. The above answer corresponds to the real part of this computation with $f(z) = e^z$.







        share|cite|improve this answer














        share|cite|improve this answer



        share|cite|improve this answer








        edited 1 hour ago

























        answered 2 hours ago









        Sangchul Lee

        90.6k12163262




        90.6k12163262






























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