User guide
E-scooter braking technique: progressive squeeze, threshold braking, weight transfer, dry vs wet, regen integration
An e-scooter's stopping distance isn't a brake spec — it's the sum of the rider's reaction distance (≈1.5 s × speed) and physical braking distance ½v²/(μg), which grows quadratically with speed: at 25 km/h reaction-plus-braking is ≈14–15 m on dry, at 45 km/h it's already 30–35 m, at 65 km/h over 60 m. The tire-road friction coefficient μ_dry ≈0.7 on clean asphalt drops to μ_wet ≈0.3 in rain, μ_paint ≈0.1 on fresh markings, and μ_steel ≈0.1 on wet manhole covers — meaning the same speed needs two to seven times more distance. Under a hard stop, weight transfers forward to 70–80 % because of the rider's high CoG and the e-scooter's short wheelbase, so the front mechanical disc does the bulk of the work and the rear (mech or regenerative) helps. Threshold braking means decelerating just below the lockup point, because μ_static > μ_kinetic. Progressive squeeze (force ramping over 0.2–0.3 s) lets weight transfer to the front wheel before full torque is applied — otherwise the front locks before it's loaded and you go over the bars. Regenerative braking delivers up to 20 % of mechanical peak and **vanishes at low speed** (no back-EMF), so an emergency stop without mech brakes is impossible. This guide is drill-oriented: physics, weight transfer, progressive vs grab, dry vs wet vs paint vs steel, regen integration, a 4-step emergency-stop protocol. ENG-first sources: MSF Basic RiderCourse Quick Tips, IAM RoadSmart, RoSPA, NHTSA/FHWA stopping-distance data, IIHS friction tables, Cycling UK braking guide, Park Tool / Sheldon Brown bicycle dynamics, Helsinki TBI series (PMC 8759433).