You start by setting z=C (or, basically equivalently as it happens, z=0) and then repeatedly setting z := z^2+C. Keep doing this until you get a z with |z|>Rmax.

If you never do -- of course in practice you won't go on literally for ever, but will stop after a certain maximum number of iterations -- then your point is in the Mandelbrot set, and if you're drawing a picture you typically colour it black.

If after N iterations you *do* get |z|>Rmax, then your point wasn't in the Mandelbrot set, and N gives some indication of how thoroughly outside the set it is; if you're drawing a picture, you typically plot the point in a colour determined by N.

The description of L_n on the Wolfram page is pretty bad. What they mean is: define L_n(C) to be the value of z after n iterations when you use the parameter C; then you can plot the curves defined by |L_n(c)|=Rmax. These are the boundaries between the different-coloured regions when you plot points as described above.