Can anyone help with how to evaluate the following integral $$ \int_0^\infty\sin{(x^4)} dx $$ I know that I need to use the fact that $\int_0^\infty e^{-x^4}dx=\Gamma\left(\dfrac{5}{4}\right)$ and I know that I have to use Eulers formula and contour integration but I am really lost on how to start the problem.


Solution 1:

Consider the contour integral $\int_{\Gamma(R)} e^{-z^4}\, dz$, where $\Gamma(R)$ is the first quadrant sector of the quarter circle (centered at the origin), subtended by the angle $\pi/8$, with counterclockwise orientation. Then $\Gamma = \gamma_1 + \gamma_2 + \gamma_3$, where $\gamma_1$ is the line segment from $0$ to $R$, $\gamma_2$ is the arc of the sector, and $\Gamma_3$ is the line segment from $Re^{i\pi/8}$ to $0$. Along $\gamma_2$, $z = Re^{it}$, $0 \le t \le \pi/8$, so

$$|e^{-z^4}| = |e^{-R^4(\cos 4t+ i\sin 4t)}| = e^{-R^4\cos 4t}.$$

Since $\cos 4t \ge 1 - 8t/\pi$ for $0 \le t \le \pi/8$, $|e^{-z^4}| \le e^{-R^4}e^{8R^4t/\pi}$. Therefore

$$\left|\int_{\gamma_2} e^{-z^4}\, dz\right| \le e^{-R^4}\int_0^{\pi/8} e^{8R^4t/\pi} R\, dt = Re^{-R^4}\cdot \frac{\pi(e^{R^4} - 1)}{8R^4} = \frac{\pi}{8R^3}(1 - e^{-R^4})$$

The last expression tends to $0$ as $R\to \infty$. Since $\int_{\Gamma(R)} e^{-z^4}\, dz = 0$ by Cauchy's theorem, we have

$$0 = \lim_{R\to \infty} \left(\int_{\gamma_1} e^{-z^4}\, dz + \int_{\gamma_3} e^{-z^4}\, dz\right).$$

Along $\gamma_3$, $z = re^{i\pi/8}$, $0 \le r \le R$. Thus

$$\int_{\gamma_3} e^{-z^4}\, dz = -\int_0^R e^{-r^4e^{i\pi/2}}\, e^{i\pi/8}\, dr = -e^{i\pi/8}\int_0^R e^{-ir^4}\, dr.$$

Since

$$\int_{\gamma_1} e^{-z^4}\, dz + \int_{\gamma_3} e^{-z^4}\, dz = \int_0^R e^{-x^4}\, dx - e^{i\pi/8} \int_0^R e^{-ix^4}\, dx,$$

we deduce that

\begin{align}0 &= \int_0^\infty e^{-x^4}\, dx - \int_0^\infty e^{-i(x^4 - \pi/8)}\, dx\\ 0&= \Gamma(5/4) - \int_0^\infty [\cos(x^4 - \pi/8) + i \sin(x^4 - \pi/8)]\, dx\\ \Gamma(5/4)&= - \int_0^\infty (\cos(x^4)\cos(\pi/8) + \sin(x^4)\sin(\pi/8))\, dx\\& + \int_0^\infty (\sin(x^4)\cos(\pi/8) - \cos(x^4)\sin(\pi/8))\, dx\end{align}

Taking the real and imaginary parts, we obtain a system of equations

\begin{align} A\cos \pi/8 + B\sin \pi/8 &= \Gamma(5/4)\\ -A\sin \pi/8 + B\cos \pi/8 &= 0 \end{align}

Here $A = \int_0^\infty \cos(x^4)\, dx$ and $B = \int_0^\infty \sin(x^4)\, dx$. The solution is

\begin{align} A &= \cos(\pi/8)\Gamma(5/4)\\ B &= \sin(\pi/8)\Gamma(5/4) \end{align}

That is,

$$\int_0^\infty \sin x^4\, dx = \sin(\pi/8)\Gamma(5/4), \quad \int_0^\infty \cos x^4\, dx = \cos(\pi/8)\Gamma(5/4).$$

Solution 2:

Hint. Here is an approach.

Recall that, from the definition of the Euler $\Gamma$ function, we have $$ \begin{align} \int_{0}^{\infty} e^{-bt} \, t^{s} \, dt = \frac{\Gamma(s+1)}{b^{s+1}}, \quad s>-1, \Re b>0. \tag1 \end{align} $$ Put $b_\epsilon=\epsilon+i,\, \epsilon>0$, in $(1)$, then let $\epsilon \to 0^+$ to get $$ \begin{align} \int_{0}^{\infty} t^{s} \sin t \, dt & = \cos \left(\frac{\pi s}{2}\right)\Gamma(s+1), \quad -1<s<0. \tag2 \end{align} $$ Now, by the change of variable $t=x^4$, $x=t^{1/4}$, $dx=\frac14 t^{-3/4}dt$ we have $$ \begin{align} \int_{0}^{\infty} \sin (x^4) \, dx & = \frac14\int_{0}^{\infty} t^{-3/4} \sin t \, dt =\frac14\cos \left(\frac{3\pi }{8}\right)\Gamma(1/4)=\frac{\sqrt{2-\sqrt{2}}}{8}\Gamma(1/4). \tag3 \end{align} $$