This is the heart of the PDF you seek. It’s why you can measure the pressure of a gas in a box by watching one molecule for a long time (time average) or by averaging over all molecules at once (space average). The gas is an ergodic system.
Imagine a simple dynamical system: on a circle. You have a point on a circle (an angle from 0 to 1). The rule: multiply the angle by 2, and take the fractional part. Start at 0.1. The orbit: 0.1 → 0.2 → 0.4 → 0.8 → 0.6 → 0.2 → ... It’s deterministic. dynamical systems and ergodic theory pdf
You click on the PDF. The first equation stares back: [ \lim_{n\to\infty} \frac{1}{n} \sum_{k=0}^{n-1} f(T^k x) = \int_X f , d\mu ] That is the Ergodic Theorem. On the left, a single orbit—one drop in an infinite ocean. On the right, the whole space—the ocean itself. The equals sign is a bridge between the deterministic and the statistical, the predictable and the random. This is the heart of the PDF you seek