Assuming the initial impulse takes the form of a sinusoid turned on abruptly at time t=0, :f(t) = \left\{ \begin{array}{rl} 0 & t then we can write the general-form integral given in the previous section as :f(x,t)=-\frac{1}{\tau} \int e^{-i (k(\omega)x-\omega t)} \frac{d\omega}{\omega^2 - (2 \pi / \tau)^2} . For simplicity, we assume the frequencies involved are all in a range of normal dispersion for the medium, and we let the dispersion relation take the form :k(\omega) = \frac{\omega}{c} \sqrt{1+\frac{a^2 \omega_0^2}{\omega_0^2-\omega^2}} where a^2= \frac{Nq^2}{m\epsilon_0 \omega_0^2}, N being the number of atomic oscillators in the medium, q and m the charge and mass of each one, \omega_0 the
natural frequency of the oscillators, and \epsilon_0 the
vacuum permittivity. This yields the integral :f(x,t)=-\frac{1}{\tau} \int \exp \left[-i \left(x\frac{\omega}{c} \sqrt{1+\frac{a^2 \omega_0^2}{\omega_0^2-\omega^2}} -\omega t\right)\right] \frac{d\omega}{\omega^2 - (2 \pi / \tau)^2} . To solve this integral, we first express the time in terms of the
retarded time t' = t-\frac{x}{c}, which is necessary to ensure that the solution does not violate causality by propagating faster than c. We also treat |\omega| as large and ignore the \frac{2\pi}{\tau} term in deference to the second-order \omega term. Lastly, we substitute \xi=\frac{a^2\omega_0^2}{2c}x, getting :f(\xi,t')=-\frac{1}{\tau} \int \exp \left[-i\left(\frac{\xi}{\omega}+\omega t'\right)\right] \frac{d\omega}{\omega^2} Rewriting this as :f(\xi,t')=-\frac{1}{\tau} \int \exp \left[-i \sqrt{\xi t'} \left(\frac{1}{\omega} \sqrt{\frac{\xi}{t'}}+\omega \sqrt{\frac{t'}{\xi}}\right)\right]\frac{d\omega}{\omega^2} and making the substitutions :\omega\sqrt{\frac{t'}{\xi}}=e^{ik}, \qquad \frac{d\omega}{\omega}=idk, \qquad \frac{d\omega}{\omega^2}=i\sqrt{\frac{t'}{\xi}}e^{-ik} dk allows the integral to be transformed into :f(\xi,t')=-\frac{i}{\tau} \sqrt{\frac{t'}{\xi}} \int \exp \left[-2i \sqrt{\xi t'} \cos k\right] e^{-ik} dk , where k is simply a dummy variable, and, finally :f(\xi,t') = \frac{2\pi}{\tau} \sqrt{\frac{t'}{\xi}} J_1 \left(2\sqrt{\xi t'}\right) , where J_1 is a
Bessel function of the first kind. This solution, which is an oscillatory function with amplitude and period that both increase with increasing time, is characteristic of a particular type of precursor known as the
Sommerfeld precursor. ==Stationary-Phase-Approximation-Based Period Analysis==