[ \varepsilon(x) = \sum_{m=-\infty}^{\infty} \varepsilon_m , e^{i m K x}, \quad K = \frac{2\pi}{a} ]
[ f(x) = \frac{4}{\pi} \sum_{n=1,3,5,\ldots} \frac{\sin(nx)}{n} ] But then came the catch—the series often struggles
Even with jumps, the Fourier coefficients (\varepsilon_m) decay as (1/m) (for a step change). Meanwhile, the electric field or pressure wave is assumed to follow Bloch’s theorem: Consider a perfect square wave—a signal that jumps
The surprising answer is that when analyzing physical structures with abrupt changes—think square waves, step-index optical fibers, digital signals, or phononic crystals. e^{i n K x} ]
If you’ve ever studied Fourier series, you likely remember the core idea: any periodic function can be broken down into a sum of simple sine and cosine waves. But then came the catch—the series often struggles with discontinuities , producing that infamous 9% overshoot known as the Gibbs phenomenon. So why would anyone want to use Fourier series on discontinuous problems?
Let’s explore how engineers and physicists use Fourier series to model and solve real-world discontinuous periodic systems. Consider a perfect square wave—a signal that jumps instantly between +1 and -1. This is the poster child for discontinuity. Its Fourier series is:
[ E(x) = e^{i k x} \sum_{n=-\infty}^{\infty} E_n , e^{i n K x} ]