Everything here is computed from the equations of structural dynamics, not drawn by hand. A truck crosses, a finite-element model of the deck computes how it bends, and inverting that bending recovers the truck's weight (Bridge Weigh-in-Motion). The same vibration carries information about damage, and on a real bridge (KW51, Belgium) it tracks sixteen months of condition. The five sections below walk through this. The Math switch, top right, shows the equations and live numbers behind each step.
Tip: flip Math (top-right) at any point to see the equations behind that step.
Drag the truck across. The deck dips by less than a millimetre, but that dip, measured at a single point, is enough to recover the truck's weight while it is still moving.
Damage softens the bridge, so it vibrates a little slower. Drag the damage up and the peak frequency moves left. A passing vehicle can pick this up without any sensors on the bridge itself.
Everything so far is simulated. This is not. It is the measured natural frequency of the KW51 bridge, recorded daily for sixteen months and coloured by deck temperature.
Heavy trucks do not cause a little more damage, they cause a great deal more. A small number of overloaded trucks accounts for most of the wear, and the same method that weighs them also identifies them and estimates the cost.
Verified against closed-form physics (Frýba, modal frequencies) · validated on the real KW51 bridge · ratios exact per Eurocode EN 1993-1-9 / AASHTO · euro figures are an explicit asset-depreciation illustration. See REPORT.pdf.
Built on real physics, checked against textbook formulas and a real bridge. Flip the Math switch (top-right) to see the equations.
A half-kilometre viaduct on its piers, carrying a full stream of cars and trucks with dozens on the deck at once, seen from above: counting the trucks, flagging the overloaded ones, and totalling the wear they leave behind.